KR101626373B1 - Blood separating device - Google Patents

Abstract

A blood separating device according to the present invention may advantageously separate a platelet rich plasma without making blood in a container moved to another container after the blood is firstly and secondly centrifuged. Moreover, a first valve means may be opened by the rotation of any one of a first case and a second case, so a blood corpuscle component and a plasma component may be easily separated. Furthermore, a second valve means may be opened by the rotation of any one of the second case and a third case, so a platelet rich plasma and a platelet poor plasma may be easily separated. Since the degree of opening is adjusted according to rotation angles of the first and second valve means, a boundary surface between a plasma component and a blood corpuscle component or a boundary surface between a platelet rich plasma and a platelet poor plasma may be more easily and precisely separated. The first and second valve means are formed to be opened when each of opening parts is opened, so an opened flow path area is minimized and a small quantity of a plasma component or a platelet rich plasma may be more precisely fed and discharged. Accordingly, blood separation may be more easily performed. The first and second valve means are formed to be gradually opened and to be gradually shielded according to rotation angles thereof, so a small quantity of a plasma component or a platelet rich plasma may be more slowly fed and discharged and of a boundary surface therebetween may be more precisely separated. A platelet rich plasma separated and accommodated in the third case is extracted by using a syringe and may be immediately fed into a patient. Consequently, blood is not exposed to air, and occurrence of contamination may be prevented.

Description

Blood separating device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a blood separator, and more particularly, to a blood separator that can more easily separate platelet-rich plasma from blood.

In general, blood is separated into red blood cells, white blood cells, platelets and plasma components by centrifugation or membrane separation. When the blood is separated by centrifugation, it is separated into blood cells and plasma according to its weight. Separated plasma is divided into Platelet Rich Plasma (PRP) and Platelet Poor Plasma (PPP). The platelet-rich plasma is obtained by centrifuging blood at a low rate with a plasma component rich in platelets. The platelet-rich plasma is obtained by centrifuging blood at high speed into plasma containing less platelets. Since platelets, which play an important role in wound healing and skin regeneration, are contained at a high concentration in the platelet-rich plasma, they have recently been used in various fields such as pain treatment, hair loss treatment, and skin regeneration.

Therefore, the blood is firstly centrifuged and separated from the blood into blood cells and plasma, and then the separated plasma is subjected to secondary centrifugation again to separate platelet-rich plasma.

However, the conventional blood separator has a problem that the blood may be exposed to the atmosphere during the movement of blood during the first and second centrifugation, and it is very difficult to separate the platelet-rich plasma at a high concentration.

Korean Patent No. 10-1005970

It is an object of the present invention to provide a blood separation device capable of more easily separating platelet-rich plasma.

A blood separator according to the present invention comprises a first case in which a hemocomponent component and a plasma component are stacked and housed in a first centrifugation of blood and in which a plasma outlet through which the plasma component flows out is formed, A first water level-up member for pushing the plasma component in the first case to be discharged through the plasma outlet; and a plasma inlet connected to the plasma outlet of the first case, A second case in which plasma components are stacked up and stacked as a platelet-rich plasma and an empty platelet plasma upon secondary centrifugation and a plasma separation port is formed so that the separated platelet-rich plasma and the vacated platelet plasma are separated and released; A platelet-rich plasma separation port communicating with the plasma separation port of the second case is formed, and the multi-platelet plasma separation port A second water level-up member provided in the third case and pushing the empty platelet plasma introduced into the third case to be discharged through the platelet-rich plasma separation port; A first valve means installed to be rotatable in at least one of the outlet and the plasma inlet so as to adjust the degree of opening and closing of the plasma outlet and the plasma inlet according to the angle of rotation and at least one of the plasma separator and the platelet- And a second valve means installed to be rotatable in one of the plasma separator and the platelet separator according to the rotation angle.

The blood separation device according to another embodiment of the present invention includes a first case in which a blood cell component and a plasma component are stacked and housed in a first centrifugation of blood and in which a plasma outlet through which the plasma component flows out is formed, A first water level-up member provided in the first case and pushing the plasma component in the first case to be discharged through the plasma outlet; and a plasma inlet connected to the plasma outlet of the first case, The plasma component introduced through the first and second centrifugal separators is stacked up and down as platelet platelets and free platelet plasma in the second centrifugation, and the second platelet plasma is separated from the second platelet plasma, And a multi-platelet plasma separation port communicating with the plasma separation port of the second case is formed, and the multi-platelet plasma separation port A third case for accommodating the platelet-rich plasma, and a second level-up member provided in the third case and pushing the empty platelet plasma introduced into the third case to be discharged through the platelet- First valve means provided in at least one of the plasma outlet and the plasma inlet for opening and closing the plasma outlet and the plasma inlet, and a second valve means provided in at least one of the plasma separator and the platelet- And a second valve means for opening and closing the platelet-rich plasma separation port, wherein the first valve means comprises a plasma outlet port provided in the plasma outlet and having a first opening formed therein, And a plasma inlet cap with a second opening formed therein, wherein one of the plasma outlet cap and the plasma inlet cap And the second valve means includes a plasma separation port provided in the plasma separation port and having a third opening formed therein, And a platelet separator port provided in the platelet-rich plasma separation port and having a fourth opening formed therein, wherein any one of the plasma separation port and the platelet separation port is rotatable relative to the other And protrusions are formed along the circumferential direction on one of the outer circumferential surface of the plasma inlet and the inner circumferential surface of the plasma outlet, and the other one of the protrusions is inserted into the other of the first and second openings. Wherein the plasma inlet is inserted into the plasma outlet and rotatably coupled to the plasma outlet, The protrusions are formed along the circumferential direction in one of the inner circumferential surfaces of the platelet platelet separating spheres and grooves for inserting the protrusions are formed in the remaining one, and the plasma separating ports are inserted into the platelet separating spheres and rotated .

The blood separator according to the present invention has an advantage that the platelet-rich plasma can be separated without moving the blood to another container after the first and second centrifugation.

In addition, the first valve means can be opened by rotation of any one of the first case and the second case, so that blood cell component and plasma component can be easily separated.

Further, the second valve means can be opened by rotation of any one of the second case and the third case, so that it is easy to separate the platelet-rich plasma and the platelet-rich plasma.

In addition, since the degree of opening and closing is adjusted according to the rotation angle of the first and second valve means, the interface between the plasma component and the blood cell component or the interface between the platelet-rich plasma and the platelet-rich plasma can be more easily and precisely separated.

In addition, since the first and second valve means are configured to be opened when the respective openings communicate with each other, the open channel area is minimized and the inflow and outflow of a small amount of plasma component or platelet plasma can be more accurately performed. There is an advantage.

In addition, since the first and second valve means are gradually opened according to the rotation angle and are gradually shielded, the flow of the small amount of plasma component or platelet plasma is performed more slowly, so that the separation of the interface is more precise .

In addition, platelet platelets separated and housed in the third case can be extracted using a syringe and directly injected into the patient, so that no air is exposed and contamination can be prevented.

1 is a cross-sectional view illustrating a blood separator according to an embodiment of the present invention.
2 is a perspective view illustrating the shielding state of the first and second valve means shown in FIG.
3 is a perspective view showing the opened state of the first and second valve means shown in FIG.
FIG. 4 is a view illustrating a method in which blood cells and plasma are separated in the blood separator shown in FIG. 1. FIG.
FIG. 5 is a diagram illustrating a method of separating an empty platelet plasma and a platelet-rich plasma in a state where the blood separator shown in FIG. 1 is turned upside down.
6 is a view illustrating first and second valve means according to another embodiment of the present invention.
7 is a view illustrating first and second valve means according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a sectional view showing a blood separator 1 according to an embodiment of the present invention.

1, a blood separator 1 according to an embodiment of the present invention includes a first case 10, a second case 20, a third case 30, a first water level elevating member 11 , A second water leveling member (31), a first valve means (110) and a second valve means (120). The first, second, and third cases 10, 20, and 30 are all made of a transparent material, and a scale (not shown) or the like may be displayed.

The first case 10 forms a space in which the blood cell component (C) and the plasma component (P) are stacked one above the other in the primary centrifugation of blood. The first case 10 includes a first tubular portion 10a to which the first level raising member 11 is coupled and a second tubular portion 10b extending from the first tubular portion 10a toward the second case 20 in the longitudinal direction And a protruded plasma outlet 10b.

The first water level elevating member (11) is coupled to the first cylindrical portion (10a). A thread is formed on the inner peripheral surface of the first cylindrical portion 10a and a thread is formed on the outer peripheral surface of the first water level elevating member 11. [ The first water level elevating member 11 is screwed to the first tubular portion 10a and moves forward to push the blood. However, the present invention is not limited to this, and it is of course possible that the first water level raising member 21 is a member capable of moving forward and backward, such as a piston.

A handle 11a is formed at a lower portion of the first water level elevating member 11. When the first water level raising member 11 is rotated, the water level raising member 11 pushes the blood in the first case 10 while moving in the vertical direction along the inner circumferential surface of the first tubular portion 10a.

The plasma outlet (10b) is a passage through which the plasma component (P) flows out to the second case (20). The plasma outlet 10b is formed to have a smaller cross-sectional area than the first cylindrical portion 10a. The first case 10 may have a smaller cross-sectional area from the first tubular portion 10a to the plasma outlet 10b. The cross-sectional area of the first tubular portion 10a may be constant, 10b may be reduced. As the cross-sectional area of the plasma outlet 10b is small and the length is long, it is easier to find and separate the interface between the blood component C and the plasma component P.

A syringe hole is formed in the first case 10 so that a syringe for extracting a blood component C separated in the first case 10 is inserted. The syringe hole is sealed by the first syringe hole cap (12). However, the present invention is not limited to this, and it is of course possible that the first case 10 and a part of the first water level elevating member 11 are made of a material such as silicone that can be inserted into the needle of the syringe.

Both ends of the second case 20 are coupled to the first case 10 and the third case 30, respectively. The second case 20 is a space in which the plasma components introduced from the first case 10 are separated and stacked vertically by multiportant plasma (PRP) and empty platelet plasma (PPP) during secondary centrifugation . The second case 20 includes a second tubular portion 20a, a plasma inlet 20b, and a plasma separator 20c.

The second cylindrical portion 20a may have a cylindrical shape with a constant cross-sectional area, and the cross-sectional area of the second cylindrical portion 20a may be gradually decreased toward the plasma inlet 20b and the plasma separator 20c.

The plasma inlet 20b is a passage through which the plasma component P discharged from the plasma outlet 10b flows. The plasma inlet 20b is formed to have a smaller cross-sectional area than the second cylinder portion 20a and is formed to be longer in the longitudinal direction. As the cross-sectional area of the plasma inlet 20b is smaller, the plasma component P can be easily separated.

The plasma inlet 20b is formed at one end of the second tubular portion 20a and is inserted and inserted into the plasma outlet 10b of the first case 10. A first projection (51) is formed along an outer circumferential surface of the plasma inlet (20b) and an inner circumferential surface of the plasma outlet (10b), and a first projection (51) Grooves 52 are formed. The first protrusion 51 is formed on the outer circumferential surface of the plasma inlet 20b and the first groove 52 is formed on the inner circumferential surface of the plasma outlet 10b. A slight gap is formed between the first projection 51 and the first groove 52 so that the plasma inlet 20b and the plasma outlet 10b are relatively rotatable. Various types of sealing members (not shown) may be provided between the plasma inlet 20b and the plasma outlet 10b. In addition to the separate sealing member, the first groove 52 and the first projection 51 may have a multi-stage structure such as a labyrinth seal, thereby improving the sealing performance. However, the present invention is not limited to this, and the plasma inlet 20b may be extrapolated to the plasma outlet 10b.

The plasma separator 20c is formed at the other end of the second cylinder 20a and is inserted into the platelet-rich plasma separator 30b of the third case 30 to be inserted thereinto. A second projection (61) is formed along the circumferential direction on one of the outer circumferential surface of the plasma separator (20c) and the inner circumferential surface of the platelet separator (30b), and the second projection A second groove 62 to be inserted is formed. In this embodiment, the second protrusion 61 is formed on the outer circumferential surface of the plasma separator 20c, and the second groove 62 is formed on the inner circumferential surface of the platelet-rich plasma separation port 30b. Explain. A predetermined gap is formed between the second projection 61 and the second groove 62 so that the plasma separation port 20c and the platelet-rich plasma separation port 30b are coupled so as to be rotatable relative to each other . A sealing member (not shown) may be provided between the plasma separator 20c and the platelet-rich plasma separator 30b. However, the present invention is not limited to this, and the plasma separation port 20c may be extrapolated to the platelet-rich plasma separation port 30b.

The plasma separator 20c separates the platelet-rich plasma (PRP) separated during the secondary centrifugation into the third case 30 or the empty platelet plasma (PPP) introduced into the third case 30, To the second cylinder portion 20a. The plasma separator 20c is formed to have a smaller cross-sectional area than the second cylinder portion 20a and is formed to be longer in the longitudinal direction. The smaller the cross-sectional area of the plasma separator 20c is, the easier it is to separate the platelet-rich plasma (PRP).

The third case (30) is rotatably coupled to the second case (20). At this time, the third case (30) is rotatable to the second case (20) but does not move linearly when rotated. That is, the platelet separator 30b of the third case 30 and the plasma separator 20c of the second case 20 are separated from the second protrusion 61 and the second groove 62, So that the third case 30 is rotatable with respect to the second case 20.

The third case 30 includes a third tubular portion 30a forming a space in which the platelet rich plasma PRP is received and a second tubular portion 30b extending from the third tubular portion 30a toward the second case 20 in the longitudinal direction And the platelet-rich plasma separator 30b protruding from the platelets 30a and 30b.

And the second water leveling member 31 is coupled to the third tubular portion 30a. A screw thread is formed on the inner circumferential surface of the third cylindrical portion 30a and a thread is formed on the outer circumferential surface of the second water level elevating member 31. [ The second water level raising member 31 is screwed to the third tubular portion 30a and moves forward to push the blood. However, the present invention is not limited to this, and it is of course possible that the second water level raising member 31 is a member capable of moving forward and backward, such as a piston.

A handle 31a is formed on the upper portion of the second water level raising member 31. When the second water level raising member 31 is rotated in the vertical direction along the inner circumferential surface of the third tubular portion 30a, Empty platelet plasma (PPP) can be pushed out.

The platelet-rich plasma separation port 30b is formed to have a smaller cross-sectional area than the third tubular portion 30a. The third casing 30 may have a smaller sectional area from the third tubular portion 30a toward the platelet-rich plasma separation port 30b, and the sectional area of the third tubular portion 30a may be constant, It is possible to reduce the cross-sectional area of the platelet-rich plasma separator 30b. As the cross-sectional area of the platelet-rich plasma separator 30b is smaller and longer, it is easier to find and separate the interface between the platelet-rich plasma (PRP) and the platelet-rich plasma (PPP).

A syringe hole is formed in the third case 30 so that a syringe for extracting platelet rich plasma (PRP) contained in the third case 30 is inserted. The syringe hole is sealed by the third syringe hole cap (32). However, the present invention is not limited to this, and a part of the third case 30 and the second water level-up member 31 may be formed of a material such as silicone that can be inserted into the needle of the syringe.

The first valve means 110 is installed to be rotatable in at least one of the plasma outlet 10b and the plasma inlet 20b so that the plasma outlet 10b and the plasma inlet 20b can be rotated, Respectively. The first valve means 110 includes a plasma outlet port 111 formed in the plasma outlet 10b and having a first opening 111a formed therein and a second opening 112a provided in the plasma inlet 20b, (Not shown).

The plasma outlet port 111 is fixed to the plasma outlet 10b and is integrally rotated when the first case 10 rotates. The plasma outlet port 111 is formed in the shape of a disk having the first opening 111a. The first opening 111a is formed in a fan shape. However, the first opening 111a is not limited to the circular shape and other shapes.

The plasma inlet port 112 is fixed to an end of the plasma inlet port 20b and is disposed in close contact with the plasma outlet port 111 in a vertical direction. The plasma inlet port 112 is formed in a disk shape having the second opening 112a, for example. The second opening 112a may have the same shape and size as the first opening 111a, or may have different shapes or different sizes. In the present embodiment, the second opening 112a is formed in the same sector shape as the first opening 111a, for example. The central point c1 of the fan shape of the second opening 112a and the central point c2 of the fan shape of the first opening 111a do not coincide with each other but are spaced apart from each other by a predetermined distance d, An example will be described in which a part is overlapped with each other.

2 and 3, the first valve means 110 is opened when the first opening 111a and the second opening 112a are communicated with each other, and the first opening 111a and the second opening 112a are opened, If the two openings 112a are not communicated, they are shielded. In this embodiment, since the first case 10 rotates, the plasma outlet port 111 integrally rotates when the first case 10 rotates, and the plasma outlet port 111 may change the position of the first opening 111a and communicate with the second opening 112a. The first case 10 and the second case 20 are provided with a scale or a marking marking the rotation angle of the first case 10 and the positions of the first opening 111a and the second opening 112a, And the like.

The second valve means 120 is rotatably installed in at least one of the plasma separator 20c and the platelet-rich plasma separator 30b, and the plasma separator 20c, And the platelet-rich plasma separator 30b is communicated or shielded. The second valve means 120 may include a plasma separator 121 provided in the plasma separator 20c and having a third opening 121a formed therein and the platelet separator 30b, And a platelet platelet separating cap 122 having a fourth opening 122a.

The plasma separation port (121) is fixed to an end of the plasma separation port (20c). The plasma separator stopper 121 is formed in the shape of a disk having the third opening 121a. The third opening 121a may have a fan shape, but the present invention is not limited thereto.

The platelet-rich plasma separating cap 122 is fixed to the platelet-rich plasma separation port 30b and is integrally rotated when the third case 30 rotates. The platelet separator 122 is rotated so that the fourth opening 122a of the platelet separator cap 122 communicates with the third opening 121a when the third case 30 rotates, It is opened. The platelet-rich plasma separating cap 122 is disposed in close contact with the plasma separating cap 121 in a vertical direction. The platelet-rich plasma separating cap 122 is formed as a disk having the fourth opening 122a, for example. The fourth opening 122a may have the same shape and size as the third opening 121a, or may have different shapes or different sizes. In the present embodiment, the fourth opening 122a is formed in the shape of a sector having the same size as the third opening 121a, for example. The central point c1 of the fan shape of the third opening 121a and the central point c2 of the fan shape of the fourth opening 122a do not coincide with each other but are spaced apart from each other by a predetermined distance d I will explain it.

The second valve means 120 is opened when the third opening 121a and the fourth opening 122a communicate with each other and when the third opening 121a and the fourth opening 122a are not communicated with each other Shielded. The opening / closing method of the second valve means 120 is the same as the opening / closing method of the first valve means 110, and a detailed description thereof will be omitted.

The second case 20 and the third case 30 are provided with a scale or a marking marking the rotational angle of the third case 30 and the position of the third opening 121a and the fourth opening 122a, And the like.

Operation of the blood separator configured as described above will be described below.

FIG. 4 is a view illustrating a method in which blood cells and plasma are separated in the blood separator shown in FIG. 1. FIG.

First, when the blood is firstly centrifuged, the blood cell component (C) and the plasma component (P) are separated and stacked in the vertical direction in the first case (10) as shown in FIG. At this time, the layer formed by the hemocomponent component (C) and the plasma component (P) can be divided into eyes according to hue, and they are classified by hatching in the drawing.

Referring to FIG. 4B, when the first level-elevating member 11 is rotated, the first level-elevating member 11 moves upward and the blood cell component C in the first case 10 and the plasma component (P) in the upward direction. Therefore, the height of the plasma component P gradually increases according to the degree of rotation of the first level-up member 11. At this time, as the cross-sectional area of the plasma outlet 10b is narrower, the height of the plasma component P may become conspicuous and the separation of the interface between the blood component C and the plasma component P may be facilitated Do.

Referring to FIG. 4C, when the upper surface of the plasma component P reaches the first valve means 110, the first valve means 110 is opened. When the first valve means 110 is opened, the plasma component P flows into the second case 20 through the plasma inlet 20b.

In order to open the first valve means 110, any one of the first case 10 and the second case 20 may be rotated relative to the other so that the first and second openings 111a, (112a). In this embodiment, for example, the first case 10 is rotated. The plasma inlet 10b and the plasma outlet 20b are coupled to the first projection 51 and the first groove 52 and are relatively rotatable. When the first case (10) is rotated, the plasma outlet plug (111) is integrally rotated. At this time, the degree of opening / closing of the first valve means 110 can be adjusted according to the degree of rotation of the plasma outlet plug 111. That is, when the plasma outlet plug 111 is rotated over a predetermined angle, at least a portion of the first opening 111a starts communicating with the second opening 112a. The first valve means 110 is partially opened from the moment at least a part of the first opening 111a starts to communicate with the second opening 112a so that the plasma component P is supplied to the second case 20 ). ≪ / RTI > 3, the entire first opening 111a is communicated with the entirety of the second opening 112a, so that the first valve unit 110 is opened, Is completely opened. When the first valve means 110 is completely opened, the plasma component P can be continuously introduced into the second case 20. [ Accordingly, the first valve means 110 is gradually opened gradually according to the communication area between the first opening 111a and the second opening 112a, whereby the plasma component P can be gradually introduced Precise separation is possible. The first valve means 110 is maintained in the open state until the interface between the plasma component P and the blood component C reaches the first valve means 110.

4D, when the interface between the plasma component P and the blood component C reaches the first valve means 110, the first valve means 110 is shielded, (C) from entering the second case (20). Referring to FIG. 2, when the first case 20 is rotated, the first opening 111a is gradually rotated to a position where it is not communicated with the second opening 112a, Gradually shielded.

Therefore, the plasma component (P) flows into the second case (20), and only the blood component (C) remains in the first case (10). The hemocomponent component (C) contained in the first case (10) can be extracted through the syringe hole. The plasma component (P) contained in the second case (20) can be separated into the platelet rich plasma (PRP) and the empty platelet plasma (PPP) by secondary centrifugation and a method described later.

As described above, the first valve means 110 is rotated according to the position of the interface between the plasma component P and the blood component C to adjust the opening and closing of the plasma component P and the blood component C is easy to separate. Further, since the degree of opening / closing is adjusted according to the rotation angle of the first valve means 110, separation of the interface between the plasma component P and the blood component C is easier and more precise.

FIG. 5 is a diagram illustrating a method of separating an empty platelet plasma and a platelet-rich plasma in a state where the blood separator shown in FIG. 1 is turned upside down.

Referring to FIG. 5, after separating the plasma component (P) and the blood component (C), the blood separator (1) is turned upside down. When the blood separator 1 is reversed upside down, the third case 30 is positioned on the lower side and the first case 10 is positioned on the upper side.

5A, when the second case 20 is subjected to secondary centrifugation in a state in which the plasma component P is accommodated, the plasma component P is recovered from the platelet rich plasma (PRP) (PPP). At this time, the layer formed by the platelet-rich plasma (PRP) and the platelet-rich plasma (PPP) may be classified into hatches by color, and different hatching groups are shown in the figure.

Referring to FIG. 5B, the second valve means 120 is opened to separate the platelet rich plasma (PRP) from the second case 20 into the third case 30. When the second valve means 120 is opened, the platelet rich plasma (PRP) flows into the third case 30 through the plasma separator 20b.

In order to open the second valve means 120, any one of the second case 20 and the third case 30 may be rotated relative to the other to open the third opening 121a and the fourth opening 30a, (122a). In the present embodiment, the third case 30 is rotated by way of example. The plasma separator 20c and the platelet-rich plasma separator 30b are coupled to the second protrusions 61 and the second grooves 62 to be relatively rotatable. When the third case 30 is rotated, the platelet-rich plasma separation port 122 is integrally rotated. At this time, the degree of opening and closing of the second valve means 120 can be adjusted according to the degree of rotation of the platelet separator 122. That is, at least a portion of the third opening 121a starts communicating with the fourth opening 122a when the platelet separator 122 is rotated over a predetermined angle. The second valve means 120 is partially opened from the moment at least a part of the third opening 121a starts to communicate with the fourth opening 122a so that the platelet rich plasma PRP is transferred to the third case 30). ≪ / RTI > That is, the platelet-rich plasma (PRP) can be slowly introduced. When the platelike plasma separation port 122 is continuously rotated, the entirety of the third opening 121a communicates with the entirety of the fourth opening 122a, and the second valve means 120 is completely opened . The second valve means 120 is completely opened, and the platelet rich plasma (PRP) can be continuously introduced into the third case 30. The open state of the second valve means 120 is maintained until the interface between the platelet rich plasma (PRP) and the empty platelet plasma (PPP) reaches the second valve means (120).

Referring to FIG. 5C, the interface between the platelet rich plasma (PRP) and the empty platelet plasma (PPP) reaches the second valve means 120 to shield the second valve means 120.

In the meantime, when a part of the blood platelet PPP flows into the third case 30, the second water level-up member 31 is rotated so that the second water level- The interface between the empty platelet plasma (PPP) and the platelet rich plasma (PRP) is moved upward.

5D, the second water leveling member 31 is rotated until the interface between the empty platelet plasma (PPP) and the platelet-rich plasma (PRP) reaches the second valve means 120. When the upper surface of the platelet rich plasma (PRP) reaches the second valve means (120), the second valve means (120) is opened. When the second valve means 120 is opened, the empty platelet plasma (PPP) flows into the second case 20 through the plasma separator 20c.

When the interface between the empty platelet plasma (PPP) and the platelet rich plasma (PRP) reaches the second valve means (120), the second valve means (120) is shielded.

 Therefore, the empty platelet plasma (PPP) is separated and accommodated in the second case 20, and only the platelet rich plasma (PRP) remains in the third case 30. The platelet rich plasma (PRP) contained in the third case 30 can be extracted through the syringe hole and administered directly to the patient.

As described above, by opening and closing the second valve means 120 by rotating the second valve means 120 according to the position of the interface between the empty platelet plasma (PPP) and the platelet rich plasma (PRP), the empty platelet plasma (PPP) The separation of the platelet-rich plasma (PRP) interface is easy.

Further, since the degree of opening / closing is adjusted according to the rotation angle of the second valve means 120, separation of the interface between the empty platelet plasma (PPP) and the platelet-rich plasma (PRP) can be more easily and accurately performed.

6 is a view illustrating first and second valve means according to another embodiment of the present invention.

6, the first valve means 210 according to another embodiment of the present invention includes a first stop 211 provided in the plasma outlet 10b and having a first opening 211a, And a second stopper 212 provided on the inlet 20b and having a second opening 212a formed to communicate with the first opening 211a. The first opening 211a is a circular hole, The two openings 212a are different from the above embodiment in that they have a fan shape, and only different configurations will be described in detail below. Since the second valve means provided between the second case 20 and the third case 30 is the same as the first valve means 210, the detailed description will be omitted.

At least a part of the first opening 211a and the second opening 212a may be opened or closed according to the rotation angle of the first stopper 211. At this time, the flow passage area opened when the first opening 211a and the second opening 212a communicate with each other corresponds to the area of the first opening 211a.

Therefore, since the first opening 211a is formed as a circular hole, the opening area of the channel is minimized, and a small amount of plasma component or platelet plasma can be flowed in and out more precisely, which is advantageous in blood separation .

7 is a view illustrating first and second valve means according to another embodiment of the present invention.

7, the first valve means 310 according to another embodiment of the present invention includes a first stop 311 provided in the plasma outlet 10b and having a first opening 311a, And a second stopper 312 provided at the plasma inlet 20b and having a second opening 312a formed therein to communicate with the first opening 311a. One end of the first stopper 311 is connected to the plasma outlet And the other end is protruded toward the plasma inlet 20b so as to be inserted into the plasma inlet 20b and the second stopper 312 is formed to be elongated in the longitudinal direction of the plasma inlet 20b Is different from the above embodiment, and only different configurations will be described in detail. Since the second valve means provided between the second case 20 and the third case 30 is the same as the first valve means 310, a detailed description thereof will be omitted.

A portion of the first stopper 311 is inserted into the plasma inlet 20b so as to reinforce the connection portion between the plasma outlet 10b and the plasma inlet 20b.

Therefore, even if the cross-sectional area of the plasma outlet 10b and the plasma inlet 20b is reduced for more precise separation, the first plug 311 and the second plug 312 can reinforce the strength.

Even if the cross-sectional area of the plasma outlet 10b and the plasma inlet 20b is increased, the size of the first plug 311 and the second plug 312 can be adjusted, There is an advantage that the channel area opened when the second opening 312a is communicated can be reduced.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: first case 10b: plasma outlet
20: second case 20b: plasma inlet
20c: plasma separation port 30: third case
30b: platelet platelet separation port 51: first projection
52: first groove 61: second projection
62: second groove 110: first valve means
111: plasma outlet plug 111a: first opening
112: plasma inlet cap 112a: second opening
120: second valve means 121: plasma separator stopper
121a: third opening 122: platelet platelet separating cap
1223a: fourth opening

Claims (13)

A first case in which a blood cell component and a plasma component are stacked and housed in a first centrifugation of blood and in which a plasma outlet through which the plasma component flows out is formed;
A first water level-up member provided in the first case and pushing the plasma component in the first case to be discharged through the plasma outlet;
A plasma inlet which is inserted into the plasma outlet of the first case and is connected to the plasma outlet to form a plasma inlet which is a passage through which the plasma component is introduced and a plasma component introduced through the plasma inlet during the secondary centrifugation, A second case in which a plasma separator is formed so as to be vertically stacked with plasma and an empty platelet plasma and to separate and separate the platelet-rich plasma and the free platelet plasma from each other;
A third case in which a platelet-rich plasma separation port communicating with the plasma separation port of the second case is formed, and the platelet-rich plasma introduced into the platelet-rich plasma separation port is accommodated;
A second water level-up member provided in the third case and pushing the empty platelet plasma introduced into the third case to be discharged through the platelet-rich plasma separation port;
First valve means installed to be rotatable in at least one of the plasma outlet and the plasma inlet and adjusting the opening and closing degree of the plasma outlet and the plasma inlet according to the rotation angle;
And second valve means installed to be rotatable in at least one of the plasma separator and the platelet-separating plasma to adjust the degree of opening and closing of the plasma separator and the platelet separator according to the rotation angle,
Wherein the plasma outlet is formed to have a smaller cross sectional area than a first tubular portion to which the first level rising member is screwed in the first case and is protruded in the longitudinal direction from the first tubular portion toward the second case,
Wherein the plasma inlet is formed to have a cross sectional area smaller than that of the second tubular portion at one end of a tubular tubular portion having a constant sectional area in the second case and is formed to be long in the longitudinal direction toward the plasma outlet, So that the plasma can be relatively rotated with respect to the plasma outlet,
Wherein the plasma separator is formed to have a cross sectional area smaller than that of the second tubular portion at the other end of the second tubular portion and is elongated in the longitudinal direction toward the platelet-rich plasma separation port, and the platelet- So that they can rotate relative to each other,
The platelet-rich plasma separator is formed to have a smaller cross-sectional area than a third tubular portion to which the second level-rising member is screwed in the third case, and is protruded from the third tubular portion toward the second case in the longitudinal direction ,
Wherein the first valve means comprises a plasma outlet cap fixed to the plasma outlet and integrally rotated when the first case rotates and having a first opening, And a plasma inlet cap having a first opening and a second opening communicating at least a portion with the first opening,
Wherein the plasma outlet cap
Wherein one side is provided on the inner circumferential surface of the plasma outlet and the other side is protruded in the longitudinal direction toward the plasma inlet so as to be inserted into the plasma inlet so as to reinforce the connection portion between the plasma outlet and the plasma inlet. The method according to claim 1,
Wherein the plasma inlet cap comprises:
Wherein the blood inlet is elongated in the longitudinal direction of the plasma inlet to reinforce the plasma inlet. delete The method according to claim 1,
Wherein the plasma inlet is inserted into the plasma outlet,
Wherein protrusions are formed along the circumferential direction on one of the outer circumferential surface of the plasma inlet and the inner circumferential surface of the plasma outlet and the other has a groove into which the protrusion is inserted. delete The method according to claim 1,
Wherein the second valve means comprises:
A plasma separation port fixed to the plasma separation port and having a third opening,
A blood platelet separator cap fixed to the platelet-rich plasma separation port and integrally rotated upon rotation of the third case and having a fourth opening communicating with at least a part of the third opening at the time of rotation, Separating device. delete The method according to claim 1,
Wherein the plasma separator is inserted into the platelet-rich plasma separator,
Wherein a protrusion is formed along the circumferential direction on one of an outer circumferential surface of the plasma separation port and an inner circumferential surface of the platelet-rich plasma separation port, and the other has a groove into which the protrusion is inserted. The method of claim 6,
Wherein the plasma separator stopper comprises:
Wherein one side is provided on the inner circumferential surface of the plasma separation port and the other side is protruded in the longitudinal direction toward the platelet-like plasma separation port so as to be inserted into the platelet-rich plasma separation port. delete delete delete delete

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